JPH06283146A - Halogen lamp - Google Patents

Abstract

PURPOSE:To provide a halogen lamp capable of extending its life without reducing the stability and efficiency in manufacturing. CONSTITUTION:A halogen lamp 1 is provided with a bulb 2, a seal section 3 sealing the bulb 2, a filament 4 arranged at the prescribed position in the bulb 2, and a infrared reflecting film 8 formed on the outer face of the bulb 2. The bulb 2 is formed into the shape combined with part 11 of a spherical body 10 and part 13 of a spheroid 12 at the prescribed ratio. The filament 4 is arranged between the focal point F1 of the spherical body 10 and the focal point F2 of the spheroid 12, and the seal section 3 is provided on the spherical body 10 side.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a halogen lamp, and more particularly to a halogen lamp having an infrared reflection film formed on the outer surface of a bulb.

[0002]

2. Description of the Related Art A halogen lamp is a lamp that can be made smaller, have a longer life, and have higher efficiency than an incandescent light bulb by enclosing halogen such as iodine in a bulb and performing a halogen cycle. is there.

Some halogen lamps have an infrared reflecting film formed on the outer surface of the bulb.

The infrared reflection film is one of the optical interference films in which substances having different refractive indexes are layered, and has a property of returning the infrared light emitted from the filament to the filament again and transmitting only visible light. A halogen lamp with a reflective film has lower power consumption and an efficiency (Lm / W) of 1 compared to a halogen lamp with the same voltage that is not formed.
There is a merit that it will improve by about 5%.

[0005]

When the bulb shape of the halogen lamp is made spherical, the energy of the infrared rays reflected by the infrared reflection film is concentrated on a specific part of the filament, so-called hot spot is formed and the filament is broken early. Resulting in.

On the other hand, if the bulb shape of the halogen lamp is made into a spheroid, the energy of the infrared rays reflected by the infrared reflecting film is placed at a specific portion of the filament by arranging the filament between two focal points of the spheroid. Concentration is stopped, hot spots are not formed, and early disconnection can be avoided.

However, in the spheroidal type, since the distance from the sealing portion to the filament is longer than that of the spherical bulb, the position of the molybdenum foil in the sealing portion is almost the same, so that the filament inevitably has to be formed. You have to lengthen the leg.

Therefore, the spheroidal type has another problem that the manufacturing stability is lowered and the voltage loss is increased to lower the efficiency.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a halogen lamp capable of achieving a long life without lowering the manufacturing stability and efficiency.

[0010]

In order to achieve the above object, the halogen lamp of the present invention has a bulb, a sealing portion for sealing the interior of the bulb, and a interior of the bulb as described in claim 1. In a halogen lamp having a filament arranged at a predetermined position and having an infrared reflection film formed on the outer surface of the bulb, the bulb has a shape obtained by combining a part of a sphere and a part of a spheroid with a predetermined ratio. And the filament is disposed between the focal point of the sphere and the focal point of the spheroid, and the sealing portion is provided on the sphere side.

[0011]

In the halogen lamp of the present invention, the infrared rays radiated from the filament are reflected by the infrared reflection film formed on the outer surface of the bulb and returned to the inside of the bulb, but the filament is focused on the sphere and the spheroid. Since the infrared energy is not concentrated in a specific area of the filament, a hot spot is not formed in the filament. Further, since the sealing portion is provided on the spherical side of the bulb, the distance from the sealing portion to the filament is shortened to the same length as in the case of the spherical bulb. Therefore, the leg of the filament is also shortened, and an increase in voltage loss can be prevented.

[0012]

Embodiments of the halogen lamp of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a vertical sectional view of the halogen lamp of this embodiment.

As shown in the figure, in the halogen lamp 1 of this embodiment, an inert gas and a small amount of iodine, which is a halogen group element, are enclosed in a bulb 2 made of glass, and both ends thereof are provided with a tip portion 9 and It is sealed with the sealing portion 3. A filament 4 is arranged in the bulb 2, and electric power is supplied from the outside through the legs 5a and 5b connected to both ends, the molybdenum foils 6a and 6b and the pins 7a and 7b. Further, an infrared reflection film 8 that reflects infrared rays emitted from the filament 4 is formed on the outer surface of the bulb 2.

The infrared reflecting film 8 is preferably formed by alternately stacking titanium dioxide which is a high refractive index layer and silicon dioxide which is a low refractive index layer.

In this embodiment, the valve 2 is formed in a shape in which a part 11 of the sphere 10 and a part 13 of the spheroid 12 are combined at a predetermined ratio. The part 11 of the sphere may be, for example, one half to one third of the sphere 10.

The filament 4 is arranged between the focal point of the sphere 10, that is, the center F ₁ and the focal point F ₂ of the spheroid 12, and the sealing portion 3 is provided on the sphere 10 side.

In the halogen lamp 1 of this embodiment,
The infrared rays emitted from the filament 4 are reflected by the infrared reflection film 8 formed on the outer surface of the bulb 2 and returned to the inside of the bulb 2, but the filament 4 is focused on the focus F _{1 of the} sphere 10 and the focus F of the spheroid 12. because disposed between the _two, infrared energy not concentrated in a specific area of the filament 4, the filament 4 is generally heated. Therefore, no hot spot is formed on the filament 4.

FIG. 2 shows experimental data showing the relationship between the filament position and the filament temperature for each of the present example and the conventional example (a spherical halogen bulb having an infrared reflection film formed on the outer surface of the bulb). is there. This experiment was carried out by arranging the halogen lamp 1 so that the pins 7a and 7b face vertically upward. The black points indicate the present embodiment, and the white points indicate the conventional example.

In the figure, the abscissa is the uppermost position (“UPPER”) of the filament 4 at the origin, and the position is 1
The filament positions of the first winding (# 1), the second winding (# 2) ... The vertical axis shows the temperature at each filament position, but the maximum filament temperature in the conventional example is 100%, and the other temperatures are shown as relative values standardized by this maximum filament temperature. .

As shown in FIG. 2, in the conventional spherical halogen lamp, the temperature is high at the center of the filament. This indicates that the radiant energy of infrared rays reflected from the infrared reflecting film is concentrated in the center of the filament.

On the other hand, in the halogen lamp of the present embodiment, the temperature distribution does not increase in the center of the filament, but the distribution is relatively uniform. This shows that the energy of reflected infrared rays was not concentrated in the center of the filament but was dispersed over the entire filament because the filament 4 was placed away from the focal points F ₁ and F ₂ .

Further, in the halogen lamp of this embodiment, since the sealing portion 3 is provided on the sphere 10 side of the bulb 2, the distance from the sealing portion 3 to the filament 4 is the same as that of the spherical bulb. Is shortened. Therefore, the legs 5a and 5b of the filament 4 are also shortened to the same length as in the case of the spherical bulb.

As described above, in the halogen lamp of this embodiment, the bulb is formed into a shape in which a part of the sphere and a part of the spheroid are combined at a predetermined ratio, and the filament is the focus of the sphere. Since it is arranged between the spheroid and the focal point of the spheroid, it is possible to disperse the infrared energy reflected by the infrared reflecting film in the entire filament without concentrating it in the center of the filament.

Therefore, there is no possibility of forming hot spots on the filament, and the life of the lamp can be extended as compared with the conventional spherical halogen lamp. Specifically, the life of the conventional lamp was 3000 hours, whereas in the present example, the life could be improved to 4000 hours.

Further, in the halogen lamp of this embodiment, since the sealing portion is provided on the sphere side, the leg of the filament can be shortened to the same length as the spherical halogen lamp.

Therefore, also in the halogen lamp of this embodiment, the manufacturing stability equivalent to that of the spherical halogen lamp can be ensured, and the power loss in the leg is not increased, so that the efficiency equal to that of the spherical halogen lamp can be maintained.

[0028]

As described above, the halogen lamp of the present invention comprises a bulb, a sealing portion for sealing the inside of the bulb,
A halogen lamp having a filament arranged at a predetermined position in the bulb, wherein an infrared reflection film is formed on an outer surface of the bulb, wherein the bulb is a predetermined proportion of a part of a sphere and a part of a spheroid. Formed in a combined shape, the filament is placed between the focal point of the sphere and the focal point of the spheroid, and because the sealing portion is provided on the sphere side, stability in manufacturing and The life can be extended without lowering the efficiency.

[Brief description of drawings]

FIG. 1 is a vertical cross-sectional view of a halogen lamp of this embodiment.

FIG. 2 is a temperature distribution curve showing the relationship between the filament position and the filament temperature for each of the present example and the conventional example (a spherical halogen bulb having an infrared reflection film formed on the outer surface of the bulb).

[Explanation of symbols]

 1 Halogen Lamp 2 Bulb 3 Sealing Part 4 Filament 5 Leg 6 Molybden Foil 7 Pin 8 Infrared Reflective Film 9 Chip Part 10 Sphere 11 Part of Sphere 12 Spheroid 13 Part of Spheroid

Claims (2)

[Claims] 1. A halogen lamp comprising a bulb, a sealing portion for sealing the interior of the bulb, and a filament arranged at a predetermined position in the bulb, wherein a halogen reflecting film is formed on an outer surface of the bulb. The bulb is formed in a shape in which a part of a sphere and a part of a spheroid are combined at a predetermined ratio, and the filament is arranged between the focus of the sphere and the focus of the spheroid. A halogen lamp, wherein the sealing portion is provided on the sphere side. 2. A part of the sphere is 1/3 to 1 of the sphere.
The halogen lamp according to claim 1, which is / 2.